DE2060990A1 - Electrical switchgear with quick release - Google Patents

Description

Electrical switchgear with quick release

The invention relates to an electrical switching device with
Quick release, preferably a quick switch for
Direct current "whose" moving contact in the opening direction is constantly influenced by a spring.

In order to keep the movable contact in the switched-on position in the devices mentioned, it is already known to use a holding magnet provided with a release coil. The triggering in the event of a short circuit usually takes place in that the main current or a part of it is looped around the core of the holding magnet, thereby generating a flux which counteracts the holding flux of the magnet. A special tripping circuit with a reverse current relay is required to trigger a reverse current. As with these
If the main circuit enters the tripping system directly, the construction requires a relatively large amount of space and, from a manufacturing point of view, is mechanically complex. L) Lu construction he also does not lull the demand

109820/1071

BATH ORIGINAL

Fast triggering, as is the case, for example, with modern power converter systems with semiconductor valves.

Another known design is the movable contact arranged to be held in the engaged position by a ratchet mechanism associated with one of an electronic Current derivative trip influenced electromagnet can be triggered. The ratchet mechanism works, however among other things with the fact that relatively large masses have to be set in motion, which has a detrimental effect on the release time of the Switch affects. A mechanism of this type is also subject to wear and tear during operation can cause the switch to become mechanically unreliable after a certain period of time.

The object of the invention is to develop a switching device of the type described in the introduction, which works reliably even under strenuous operation and can be triggered much faster than previously known designs of this type. This is achieved according to the invention in that the movable contact of the switching device with a holding magnet provided with a release coil, the holding force of which comes from a permanent magnet, is held in the switched-on position, the release coil being operated in a manner known per se via an electronic and magnetically connected to the main current pathway and possibly StromderIvateriabtastenden organs f-ü £ i tüuerteö Schal tor ^ an at an i'imu'gieypeichur a

BAD ORiQtNAL ~ ^: '~

1 Ü 9 B : i) / Ii) 7 I.

is. A release system carried out in this way corresponds to the requirement for extremely short release times, which in a strongly current-limiting switches are a prerequisite.

A particularly quick release can be achieved if one A quick release magnet as a holding magnet, e.g. in the Austrian patent 185 183 described type used. The energy store advantageously consists of a capacitor and the electronic switching element of a thyristor.

The current derivative scanning element can advantageously be a special one Be a current transformer, its secondary winding via a rectifier bridge is connected to a load resistor. The triggering characteristic can be set in a simple manner can be varied by changing the load resistance, and with the help of the rectifier bridge it is achieved that the Control voltage receives the correct polarity, even if the main current has a negative direction, i.e. with reverse current.

The current level sensing element can advantageously have an iron core provided with an air gap with a tongue element in connection be at the air gap. With such an arrangement, the current level can be sampled in a very simple way, without having to intervene in the main circuit and the required isolation between the main circuit and the trip circle can also be found at the highest Reach the operating voltages occurring without difficulty.

109629/1071

In this version, too, the release characteristics can be varied easily by changing the position of the tongue element in the Relationship to the air gap changes.

Some embodiments of the invention are based on the following explained in the drawing, in which show:

1 shows a schematic diagram of a direct current high-speed switch

according to the invention,
2 shows a more detailed circuit diagram for a trip system with current derivative trip unit provided for the switch, and FIG

3 with a release system in a corresponding manner Current level release.

The high-speed switch shown in Fig. 1 is in a direct current circuit Λ and is used to interrupt short-circuit currents before they can assume impermissibly high values. The movable main contact 2 is mechanically coupled to the armature 3 of a quick release magnet 4. The magnet 4 contains a trip coil 5 and a permanent magnet which exerts a holding force on the armature 3 and thereby holds the contact 2 in the switched-on position against the force of a strong opening spring 6. The trip coil 5 is connected to a capacitor 7 via a thyristor 8. To control the thyristor 8, the switch is provided with both a current derivative scanning element and a current level scanning element, which are designated by 9 and 10, respectively. However, in most cases only one of these organs is required.

-5-1 0 9 829/10: 71

The Stromdeiivatenabtastende organ 9 consists of a special current transformer with a laminated iron core, the Main current path 1 encloses. A secondary winding sits on the iron core 11, which at a load resistance of a electronic control equipment 12 is connected, it is described in more detail in connection with FIG. The control equipment 12 is fed via terminals 13 from an operating voltage source. The current transformer 9 is dimensioned so that there is no saturation of the core in the current measuring range. This is done on the secondary side of the transformer induces an emf that leads to the current derivatives (di / dt) of the Primary side is proportional. With half the tension received the thyristor 8 is ignited »whereby the capacitor 7 discharges through the coil 5 and the switch is triggered. By changing the load resistance of the transformer, different waveforms can be created for the kitfidär voltage and thus also a certain delay in the instant of ignition obtain.

The stromniveauabtastende member 10 consists of a arranged around the main current path 1 around, with eine® air gap provided Bisenkern 14 at which r in ä & saw of the air gap, one or more peraXlelgeschaltete Zpngenelemente 15 (reed contact) are arranged, di © AusXösungeeapfind "- lichkeit is changed by that »at. z, B "by means of" iHÄT screw the position of the tongue element 15 in relation to the

Air gap changed. At a certain current level, the tongue element responds and the thyristor 8 is ignited, after which Triggering takes place.

In Fig. 2 is the design and operation of a trip system shown in more detail with current derivative trigger. An operating voltage source of e.g. 110 V direct current is between connected to the points + U and O. The capacitor 7 is via the resistors 16 and 17 and the coil 5 of the trip magnet charged. A diode 18 prevents the capacitor 7 from discharging. In normal operation, therefore, is the capacitor 7 constantly charged and therefore always ready to trigger the switch when an ignition pulse is sent to the one with the trigger coil 5 and the capacitor 7 series-connected thyristor 8 is given. The resistance of the resistor 16 must be so large, e.g. 1 kOhm, that the thyristor 8 is self-extinguishing will. The resistance of the resistor 17, on the other hand, is relatively small. The ignition pulse to the thyristor 8 comes from the Current transformer 9, which is connected to a load resistor 19 via a rectifier bridge 20. These The rectifier bridge has the task of changing the polarity of the control voltage when it is negative, e.g. when it is negative Current direction.

In parallel with the load resistor 19 is a voltage divider 21, 22, which allows an alternating setting of the voltage

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level for the ignition of the thyristor 8 allows. Because the tension of the transformer 9 is proportional to di / dt, so the desired value for the trip can easily be set. The ignition pulse is fed to the control electrode of the thyristor 8 via a resistor 23. To limit the control voltage a diode 24 or several series-connected diodes between the control electrode and the cathode of the thyristor 8 is switched on. A protection circuit for the thyristor 8, consisting of a capacitor 25 in series with a resistor 26, is interposed The anode and the cathode of the thyristor 8 are switched on. Around the ignition of the thyristor 8 a certain time after the operating voltage was interrupted to enable} the firing circuit of the thyristor contains a capacitor 27, which is connected via a voltage divider 28, 29 and a diode 30 is charged. The switch is triggered by closing a contact 31, e.g. can be controlled by a zero voltage relay, the charged capacitor 27 to the control electrode of the thyristor is connected. '.

In the release system shown in Fig. 3 with current level release most of the components of the arrangement of FIG. 2 are included. Me ignition of the thyristor 8 happens here through Closing the Zimgenelementkontakt 15 the level trigger. In order to prevent interference voltage ignition of the thyristor, its control electrode is connected in series with a resistor via a diode 32 33 connected to the earthed pole of the operating voltage source,

'i / Ί071

and for the same purpose a resistor 34 is introduced, wherein the thyristor receives negative bias. To monitor the voltage across the capacitor 7, a relay 35 is in series with a transistor 36 arranged, these components receive appropriate Voltage and current with the help of a voltage divider 37, 38, a Zener diode 39 and the resistors 40, 41, 42 and 43. Before the capacitor 7 is charged, a current flows through the transistor 36 and the relay 35, making their contact 44 closes and the actuating coil to an intermediate relay 45 via a resistor 46 receives current. It opens there is a contact 47 in the control circuit for the switch-on motor of the switch, so that the switch cannot be switched on. When the capacitor 7 is charged, the transistor 36 blocks and the relays 35 and 45 drop out, after which the switch can be switched on. An auxiliary contact 48 of the switch, which is in series with the thyristor 8, closes, so that the release system can come into operation immediately if a short circuit should occur. For manual release of the switch, a push button 49 is arranged parallel to the relay contact 44.

In order to achieve a high level of operational safety of the equipment at a relatively moderate cost, it is expedient that the Release magnet 4 (Fig. 1) is provided with two release coils, which are connected to different supply circuits, which in turn are controlled by a current-sensing element common to the circles. At such an

109829/1071

3rd order you can trigger the switch with the capacitor monitoring circuit shown in Fig. 3, if in one of the triggering circuits an error on the capacitor 7> break in the release coil 5 or a contact error in the connection between the electronic control equipment and the release coil 5 occurs. This is achieved with the help of a contact 50 on the intermediate relay 45 'which is connected in parallel with the tongue element contact 15 of the current level sensing organ. If the voltage across the capacitor 7 disappears due to one of the A above errors, the transistor 36 becomes conductive, so that the contact 50 is closed and the switch is triggered with the aid of the fault-free trip circuit operating in parallel.

To trip the switch when the operating voltage disappears should is a zero voltage relay 51 with a Zener diode 52 and a resistor 53 connected in series.

The electronic described in connection with FIGS Control equipment can be varied in many ways within the scope of the following patent claims. The one shown Equipment requires little space and all of the components except for the magnet 4 and the stroio-sensing organs 9 and 10 can expediently be based on a standard line plan can be mounted with flat pin contacts.

In the case of a switch of the type described above, a trigger time of only approx. 1 ms is measured when samples have been carried out

109829/1071 -1-0-

been. The holding force of the magnet 4 was approx. 1000 N, the load from the spring 6 approx. 500 N, the capacitance of the capacitor 7/100 / uF and the operating voltage 110 V direct current, The mentioned tripping time is significantly shorter than the corresponding time with conventional direct current high-speed switches.

109829/1071

-11-

Claims (7)

Claims; 1.1 Electrical switching device with quick release, preferably DC high-speed switch, the moving contact of which is in opening Direction is constantly influenced by a spring, characterized in that the movable contact (2) is arranged in such a way that it is connected to a Holding magnet (4), the holding force of which is based on a permanent magnet, is held in the switched-on position, the release coil (5) in a manner known per se via an electronic circuit and magnetically connected to the main current path (1) Current level and possibly current derivative scanning organs (10 or 9) controlled switching element (8) on an energy store (7) is connected. 2. Switching device according to claim 1, characterized in that the energy store (7) is a capacitor. 3. Switching device according to claim 1 or 2, characterized in that that the electronic switching element (8) is a thyristor. 4. Switching device according to one of the preceding claims, characterized in that the current level sensing organ (10) from an iron core surrounding the main current path (1) (14) with an air gap, being in or near of the air gap can be influenced by a magnetic field Element (15) -. is arranged in the control circuit for the electronic switching element (8) is switched on. 101829/1071 -12- 5. Switching device according to claim 4, characterized in that the magnetic field influenced element (15) is a tongue element. 6. Switching device according to one of the preceding claims, characterized in that the current derivative scanning element (9) is made from a current transformer loaded with a resistor (19), which is dimensioned so that in the current measuring range the transformer core is not saturated. 7. Switching device according to claim 6, characterized in that the secondary winding (11) of the current transformer (9) over a rectifier bridge (20) is connected to the load resistor (19).